Overmolded Electrical connector

ABSTRACT

An electrical connector including an electrical contact and an overmolded housing. The electrical contact includes an electrically conductive substrate of an alloy material and at least one sealing coating on a first section of the substrate. The sealing coating includes chromium and/or zinc. The overmolded electrical connector housing is overmolded onto at least a portion of the first section on the sealing coating. The sealing coating prevents a passage from forming at a joint between the contact and the overmolded housing for preventing flow of vapor and/or liquid and/or other fluid through the joint.

CROSS REFERENCE TO RELATED APPLICATION

This is a continuation patent application of U.S. patent applicationSer. No. 10/805,763 filed Mar. 22, 2004, now U.S. Patent No. 6,966,800.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to electrical connectors and, moreparticularly, to an electrical connector having an overmolded housing.

2. Brief Description of Prior Developments

One method of manufacturing electrical enclosures for use in a harshenvironment, particularly automotive, is to overmold metal electricalcurrent carrying elements, generally referred to as terminals, with oneof any number of engineering resins; thus producing an electricalenclosure with an integral electrical connector. Overmolding by itselfdoes not, however, produce a perfectly sealed device. As the plasticcools and shrinks after molding, micro gaps can form between the metaland the plastic in which fluids can wick or leak. In cases whereenvironmental sealing is required, such as for a fuel tank electricalconnector, expensive secondary operations, such as potting or gaskets,are necessitated.

A process called an A2 treatment has been developed as a dry-pack freesolution for moisture sensitive plastic surface mount packages. Unlikemost lead frame surface treatments, A2 is an ultra-thin inorganiccoating which is electro-deposited on metallic surfaces to providecoupling for polymetric adhesion. U.S. Pat. No. 5,343,073 discloses leadframes in integrated circuit (IC) packages having chromium and zincalloy coatings. U.S. Pat. No. 5,728,285 discloses an A2 treatment, butin a semiconductor on a circuit board as a protective coating; not in anelectrical connector and not to provide a sealing function.

A method for improving the adhesion of metal to plastic is desired toimprove sealing and help the device meet stringent governmentregulations for hydrocarbon vapor emissions. A treatment is desired topromote the adhesion of molding resins to metal electrical currentcarrying elements in an overmolded electrical connector. There is anexpectation that increased adhesion will greatly improve sealing. In thecase of a fuel flange, permeation of hydrocarbon vapors to theenvironment are desired to be reduced. In the case of overmoldedelectrical connectors generally, expensive secondary potting operationsare desired to be eliminated.

SUMMARY OF THE INVENTION

In accordance with one aspect of the present invention, an electricalconnector is provided including an electrical contact and an overmoldedhousing. The electrical contact includes an electrically conductivesubstrate of an alloy material and at least one sealing coating on afirst section of the substrate. The sealing coating includes chromiumand/or zinc. The overmolded electrical connector housing is overmoldedonto at least a portion of the first section on the sealing coating. Thesealing coating prevents a passage from forming at a joint between thecontact and the overmolded housing for preventing flow of vapor throughthe joint.

In accordance with another aspect of the present invention, a fuel tankelectrical connector is provided comprising a plurality of electricalcontacts, each electrical contact comprising a substrate membercomprised of a copper alloy, a first section having a sealing coatinglocated on the substrate, and at least one second section having a tincoating located on the substrate. The at least one second sectioncomprises a contact area of the contact adapted to make electricalconnection with a second electrical connector. The sealing coatingcomprises an electro-deposited inorganic coating. The overmoldedelectrical connector housing has been overmolded onto at least a portionof the first sections. The sealing coating is located at junctionsbetween the contacts and the overmolded housing. At least a portion ofeach of the second sections is located spaced from the junctions forelectrical contact with the second electrical connector. The housing isadapted to be connected to a fuel tank housing.

In accordance with one method of the present invention, a method ofmanufacturing an electrical connector is provided comprising steps ofelectro-depositing an inorganic coating to a first section of aplurality of electrical contacts; plating second sections of thecontacts with tin; and overmolding a polymer housing onto the contacts.The housing is overmolded onto the contacts with the inorganic coatingat junctions between the housing and the contacts to form a seal betweenthe housing and the contacts at the junctions. The inorganic coatingprovides adhesion and sealing as the housing cools after overmolded tothereby prevent passages or cracks from forming in the overmoldedhousing at the junctions.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and other features of the present invention areexplained in the following description, taken in connection with theaccompanying drawings, wherein:

FIG. 1 is a perspective view of a fuel tank flange comprising anelectrical connector incorporating features of the present inventionwish a partial, cutaway section of a fuel tank housing;

FIG. 2 is a perspective view of an electrical connector subassembly usedin the fuel tank flange shown in FIG. 1;

FIG. 3 is a perspective view of one of the electrical contacts used inthe electrical connector subassembly shown in FIG. 2; and

FIG. 4 is a partial cross sectional view of a portion of the electricalconnector subassembly shown in FIG. 2.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to FIG. 1, there is shown a perspective view of a flange unit10 incorporating features of the present invention shown attached to ahousing 12 of a fuel tank 14. Although the present invention will bedescribed with reference to the exemplary embodiment shown in thedrawings, it should be understood that the present invention can beembodied in many alternate forms of embodiments. In addition, anysuitable size, shape or type of elements or materials could be used. Thepresent invention is particularly adapted for use with an automobilefuel tank. Although features of the present invention are beingdescribed with reference to use with a fuel tank, features of thepresent invention could be used with any suitable type of containeradapted to contain a liquid or gas, or at any suitable barrier betweentwo areas intended to be maintained as separate.

The flange unit 10 generally comprises a frame 16, and an electricalconnector section 18. The electrical connector section 18 forms anelectrical connector with the frame 16 through the flange unit 10. Theframe 16, in this embodiment, forms part of the electrical connectorand, more specifically, forms part of the housing of the electricalconnector. The frame 16 is preferably comprised of a one-piece moldedplastic or polymer member. The frame 16 comprises tube sections 21–23.The tube sections 21–23 extend between and from a first side 24 of theframe and an opposite second side 26 of the frame. Tube sections 21–23provide conduits through the frame 16 between the first side 24 and thesecond side 26. The tube sections 20–23 also form mounting flanges forattachment of fluid/vapor/air conduits or tubes (not shown) thereto.

Referring also to FIG. 2, the electrical connector section 18 comprisesan electrical connector subassembly 28. The frame 16 is preferablyovermolded onto the subassembly 28. The subassembly 28 generallycomprises electrical contacts 30 and a subassembly housing 32. Theelectrical connector subassembly 28 comprises four of the electricalcontacts 30. However, in alternate embodiments, more or less than fourcontacts could be provided. In the embodiment shown, the electricalconnector section 18 has an electrical connector housing formed by aportion of the frame 16 and the subassembly housing 32.

Referring also to FIG. 3, one of the electrical contacts 30 is shown. Inthis embodiment the electrical connector 30 comprises a first middlesection 34 and two second connection sections 36, 38. The secondconnection section 36 comprises a male contact section which is adaptedto be removably connected to a female contact section of a contact in amating electrical connector (not shown). The mating electrical connector(not shown) is adapted to be inserted into a connector receiving area 40(see FIG. 1) formed by the frame 16 at the electrical connector section18. The second connection sections 36 extend into the connectorreceiving area 40 as shown in FIG. 1. The second connection section 38is located on the opposite side of the first middle section 34 from thesecond connection section 36. The second connection section 38 isadapted to be crimped onto an electrical conductor of an electrical wire42 (see FIG. 2). In this embodiment, the electrical contact 30 comprisesa general L shape. However, in alternate embodiments, the electricalcontacts could comprise any suitable type of shape.

Referring also to FIG. 4, each electrical contact 30 generally comprisesa substrate 44, a sealing coating 46, and a contact section coating 48.The substrate 44 comprises an electrically conductive substrate, such asa metal substrate comprised of a copper alloy. In a preferredembodiment, the substrate comprises CA19700 copper alloy. However, inalternate embodiments, any suitable type of electrically conductivematerial could be used for the conductive substrate.

The sealing coating 46 is located on the first middle section 34. In apreferred embodiment, the coating 46 is electro-deposited on the firstsection 34. The coating 46 preferably comprises an A2 treatment ofchromium and/or zinc. In one type of preferred embodiment, the coating46 comprises chromium and zinc. In particular, the coating 46 ispreferably the same as the chromium and zinc outer layer described inU.S. Pat. No. 5,343,073 which is hereby incorporated by reference in itsentirety. The A2 treatment is an ultra-thin inorganic coating which iselectro-deposited on metallic surfaces to provide coupling forpolymetric adhesion. It has been discovered that, besides providing forbetter coupling for polymetric adhesion, the A2 treatment can alsoprovide an enhanced sealing function between an electrical contact andan overmolded polymer housing. In this embodiment, the coating 46 isapplied directly to the substrate 44, such as by electroplating, beforethe subassembly housing 32 is overmolded onto the contacts 30.

U.S. Pat. No. 5,343,073 merely uses the A2 treatment for adhesion. U.S.Pat. No. 5,728,285 merely uses the A2 treatment as a protective coating.It has been discovered that the A2 treatment can be used for providingan enhanced sealing function at a sealing junction to increase thesealing efficiency between electrical contacts and an overmoldedelectrical connector housing by preventing cracks or gaps from formingin the overmolded housing when the housing cools after overmolding.

The coating 46 preferably contains chromium, zinc, or a mixture thereof.Most preferred is a mixture of chromium and zinc. The coating is thin,preferably on the order of from about 10 to about 1000 angstroms. Morepreferably, the thickness is from about 10 to about 100 angstroms andmost preferably, from about 40 to about 80 angstroms. The coating 46provides oxidation resistance and improves adhesion to a polymer resinwithout significantly reducing the strength of a wire bond ordetrimentally affecting subsequent assembly operations. The coating 46may be applied by any suitable technique such as immersion plating,electrolytic plating or cladding.

The preferred coating may be deposited by any conventional method andmay be a co-deposited layer or sequentially deposited layers of chromiumand zinc. One preferred method of depositing the coating is disclosed inU.S. Pat. No. 5,022,968 which is incorporated herein by reference in itsentirety. The patent discloses a coating layer containing chromium andzinc for anti-tarnish purposes. The coating layer is electrolyticallydeposited from a basic aqueous electrolyte containing hydroxide ions,from about 0.07 grams per liter to about 7 g/l zinc ions and from about0.1 g/l to about 100 g/l of a water soluble hexavalent chromium saltwhere the concentration of either the zinc ions or the chromium (VI)ions or both is less than 1.0 g/l. The coating layer has azinc-to-chromium ratio in excess of about 4:1. One analyzed sample hadthe composition: 5 atomic percent Cr, 21% Zn, 56% O, 16% C and 1% Cu.

The substrate housing 32 is preferably comprised of acetal. Acetal, alsoknown as polyacetal, polyoxymethylene (POM), or polyformaldehyde, is ahigh performance engineering polymer. Because of its high strength,modulus, and resistance to impact and fatigue, it is used as aweight-saving metal replacement. Acetal, first developed in the late1950s, is available as a homopolymer (such as DuPont Delrin®) orcopolymer (such as Ticona's Celcon®). In a preferred embodiment, thehousing 32 is comprised of a homopolymer acetal such as DELRIN® 100Psold by Dupont.

The subassembly housing 32 comprises an overmolded housing. Morespecifically, the subassembly housing 32 is overmolded onto the contacts30. The contacts 30 are preferably attached to the conductors of theelectrical wires 42, such as by crimping, before the subassembly housing32 is overmolded onto the contacts. The subassembly housing 32 ispreferably overmolded onto the wires 42 and their connection at thesecond connection sections 38. This provides an overmolded installationat the connection of the wires 42 with the contacts.

The second connection sections 36, 38, located at opposite ends of thecontacts 30, have the contacts section coating 48 thereon. In apreferred embodiment, the contact section coating 48 comprises tin. Thecontact section coating 48 is preferably selectively deposited on thecontacts 30 at only the second connection sections 36, 38. Tin is arelatively soft material. It will move such that oxides will crackduring connection with mating electrical conductors to allow a good aelectrical connection. Thus, a coating of tin on a contact is desirableat a connection area of the contact.

In the past, the electrical contacts were subjected to a hot tin dipped(HTD) which substantially covered the entire contact. This was arelatively inexpensive process to allow the contact areas to be coveredwith tin for good mating electrical conductor connection purposes.However, it has been discovered that overmolding a polymer housing ontoa contact entirely coated with tin allows gaps or passages to be formedbetween the overmolded housing and the tin because of the soft nature oftin. In an alternate embodiment, a material other than tin could be usedfor the contact section coating.

With the present invention, the contact section coating 48 is notapplied to the first middle section 34 of the contacts 30. As seen inFIG. 4, when the subassembly housing 32 is overmolded onto the contacts30, the housing is overmolded onto the sealing coating 46 on the firstsection 34. The first section 34 comprises a plurality of grooves ornotches 50. These grooves 50 are provided to establish a tortuous pathbetween the overmolded housing 32 and the contact 30 along the firstsection 34. This tortuous path helps to form a seal between the contacts30 and the housing 32 to prevent liquid or vapor from traveling betweenthe junctions of the overmolded housing with the contacts. The sealingcoating 46 is located at the junctions.

After the housing 32 is overmolded onto the contacts 30, the housing 32will cool. In the past, during this cooling period, cracks and gapswould form in the housing 32 at the junction with the contacts. However,it has been discovered that application of the sealing coating 46substantially prevents these cracks and gaps from forming when theovermolded housing 32 cools. Thus, an enhanced seal is provided at thejunction between the housing and the contacts at the sealing coating 46.

Providing a seal between the contacts and the overmolded housing isparticularly desirable for an electrical connector such as used with anautomobile fuel tank. The seal prevents fuel vapors from leaking out ofthe fuel tank through the electrical connector between the contacts andthe electrical connector housing. With the use of this process, theaddition of additional components, such as additional seal members orpotting material, is no longer needed. The sealing function can beprovided merely by the contacts 30 and the overmolded housing 32 withoutany additional components.

In the electrical connector subassembly 28 shown in FIG. 2, the exteriorof the subassembly housing 32 comprises grooves 52 and ridges 54. Theframe 16 is preferably overmolded onto the subassembly housing 32. Thegrooves 52 and ridges 54 provide a tortuous path between the frame 16and the subassembly housing 32 to also prevent fuel vapors fromtraveling between the two members at the junction of the two members.

Generally, in one type of conventional fuel flange seal with anelectrical connector which used a secondary operation of impregnation ofadhesive to increase sealing, leak rates in the order of about 10⁻⁵ toabout 10⁻⁶ cm³/second were provided. Tests were conducted to determinethe leak rate with the present invention. The testing equipment used avacuum on one side of the sample and Helium at a pressure of about 2.35psi on the other side of the sample. An O-ring seal was provided on thesample with the test fixture to seal the sample with the test fixture.The following chart shows the test results for 50 samples (numbered1–50):

Over Over Sample mold mold Premold Premold Leak # Shot Cavity ShotCavity Rate Comments  1 24 4B 2 A4 6.8E − 06  2 25 1B 1 A6 9.2E − 06  325 2B 1 A7 7.3E − 06  4 23 1B 4 A1 9.2E − 06  5 24 3B 1 A8 7.3E − 06  617 1B 3 A6 7.3E − 06  7 18 3B 3 A8 1.1E − 05  8 19 1B 5 A8 4.9E − 06Flaw on Sealing surface -A-  9 22 3B 4 A4 1.0E − 05 10 20 4B 4 A3 1.1E −05 11 16 3B 6 A3 8.5E − 06 Started using available rub- ber caps (Allbut one) 12 18 4B 2 A1 9.3E − 06 13 19 2B 5 A7 1.2E − 05 14 21 1B 2 A28.5E − 06 Switched back to Production caps 15 22 4B 4 A2 1.2E − 05 16 232B 3 A5 8.6E − 06 17 21 2B 2 A3 1.2E − 05 18 20 3B 5 A5 1.0E − 05 19 172B 3 A7 1.0E − 05 20 16 4B 5 A6 1.1E − 05 21  6 2B 6 A6 7.5E − 06 22  61B 6?9 A8 7.3E − 06 23 10 3B 9 A7 5.0E − 06 24 11 2B 7 A5 1.4E − 05 25 8 3B 9 A1 7.3E − 06 26 10 4B 8 A2 8.4E − 06 27 11 1B 9 A3 7.5E − 06 2812 4B 8 A4 6.6E − 06 29 12 3B 8 A1 3.9E − 06 30 14 4B 7 A8 7.6E − 06 3113 2B 7 A7 7.0E − 06 32 13 1B 7 A6 5.4E − 06 33 14 3B 6 A4 2.0E − 06O-ring on tester cleaned with handkerchief 34 15 1B 6 A2 3.7E − 06 35 152B 6 A1 4.5E − 06 36  1 2B 12 A5 2.6E − 06 37  7 1B 10 A6 5.7E − 06 38 3 1B 11 A3 2.8E − 06 Contamination in pre-mold near wire 39  3 2B 11 A42.6E − 06 40  2 4B 12 A7 6.4E − 06 41  2 3B 12 A8 1.0E − 05 Aftertesting sample 41, O-ring on tester cleaned again with handkerchief 42 4 3B 11 A1 2.5E − 07 43  5 2B 10 A7 1.2E − 07 44  7 2B 9 A5 1.1E − 0745  8 4B 9 A4 3.5E − 07 46  6 3B 10 A5 7.7E − 07 47  6 4B 10 A8 4.0E −07 48  5 1B 9 A2 4.2E − 07 49  4 4B 11 A2 4.7E − 07 50  1 1B 12 A6 5.5E− 07 Statistics Average 6.3E − 06 Max 1.4E − 05 Min 1.1E − 07 Mean 7.1E− 06 Sigma 3.9E − 06 Mean + 3 Sigma 1.9E − 05 1.9E − 05

The sample number is an identification number for the sample (50 sampleswere tested). The overmold shot is a part designation number for themold used to form the overmold portion of the flange unit. Each overmoldmold has multiple cavities for forming multiple flange units in onemolding shot process. The overmold cavity identifies the cavity of theovermold shot from which the sample was taken from. The premold shot isa part designation number for a mold used to form the premold portion ofthe flange unit. Each premold mold has multiple cavities. The premoldcavity designated the cavity of the premold shot from which the premoldportion was taken. The leak rate is in cm³/second.

As can be seen in looking at the leak rates of samples 1–41, the leakrate is about the same as a convention fuel flange which used asecondary impregnation operation to seal the flange; about 10⁻⁵–10⁻⁶cm³/second. However, the present invention can provide the same sealingcapability without the need to perform a secondary sealing operation. Inaddition, after cleaning the O-ring on the tester after sample 41, itwas noticed that lower leak rates were occurring; in the order to about10⁻⁷ cm³/second. It is believed that a speck of dust may have been onthe O-ring seal during the testing of samples 1–41 and, that the use ofthe present invention can provide a leak rate in the order of about10⁻⁶–10⁻⁷ cm³/second. This will allow connectors or electronic modulesincorporating features of the present invention to be used to meet morestringent environmental specifications expected to be enacted in thefuture, such as fuel tank hydrocarbon emissions.

It should be noted that features of the present invention can be usedwith any electronic module that needs to be environmentally sealed and,the present invention can do so without the need for potting material.It should be understood that the foregoing description is onlyillustrative of the invention. Various alternatives and modificationscan be devised by those skilled in the art without departing from theinvention. Accordingly, the present invention is intended to embrace allsuch alternatives, modifications and variances which fall within thescope of the appended claims.

1. An electrical connector comprising: an electrical contact comprisingan electrically conductive substrate and at least one sealing coating ona first section of the substrate, wherein the sealing coating comprisesan inorganic material; and an overmolded electrical connector housingwhich has been overmolded onto at least a portion of the first sectionat the sealing coating.
 2. An electrical connector as in claim 1 whereinthe sealing coating is adapted to prevent a passage from forming at ajoint between the contact and the overmolded housing for preventing flowof vapor through the joint.
 3. An electrical connector as in claim 1wherein the conductive substrate comprises a copper alloy.
 4. Anelectrical connector as in claim 1 wherein the housing comprises acetal.5. An electrical connector as in claim 1 wherein the sealing coatingcomprises an electro-deposited coating on the substrate.
 6. Anelectrical connector as in claim 1 further comprising tin plated on atleast one second section of the substrate.
 7. An electrical connector asin claim 6 wherein the tin is not located between sealing coating andthe substrate.
 8. A fuel tank electrical connector comprising anelectrical connector as in claim 1, wherein the housing is sized andshaped to be mounted to a fuel tank housing.
 9. A fuel tank electricalconnector comprising: a plurality of electrical contacts, eachelectrical contact comprising a substrate member, a first section havinga sealing coating located on the substrate, and at least one secondsection having a conductive coating located on the substrate, whereinthe at least one second section comprises a contact area of the contactadapted to make electrical connection with a second electricalconnector, and wherein the sealing coating comprises anelectro-deposited inorganic coating; and an overmolded electricalconnector housing which has been overmolded onto at least a portion ofthe first section, wherein the sealing coating is located at junctionsbetween the contacts and the overmolded housing, wherein at least aportion of each of the second sections is located spaced from thejunctions for electrical contact with the second electrical connector,and wherein the housing is adapted to be connected to a fuel tankhousing.
 10. A fuel tank electrical connector as in claim 9 wherein theelectro-deposited inorganic coating comprises at least one of chromiumand zinc.
 11. A fuel tank electrical connector as in claim 10 whereinthe electro-deposited inorganic coating comprises both chromium andzinc.
 12. A fuel tank electrical connector as in claim 9 wherein thehousing comprises acetal.
 13. A fuel tank electrical connector as inclaim 9 wherein the wherein the conductive coating comprises tin whichis not located between the sealing coating and the substrate.
 14. A fueltank electrical connector as in claim 9 wherein the wherein theconductive coating comprises tin which is selectively electroplated onthe substrate.
 15. A method of manufacturing an electrical connectorcomprising steps of: electra-depositing an inorganic coating to a firstsection of at least one electrical contact; and overmolding a polymerhousing onto the at least one electrical contact, wherein the housing isovermolded onto the at least one contact with the inorganic coating atjunctions between the housing and the at least one contact to form aseal between the housing and the at least one contact at the junctions,and wherein the inorganic coating provides adhesion and sealing as thehousing cools after overmolded to thereby substantially prevent passagesor cracks from forming in the overmolded housing at the junctions.
 16. Amethod as in claim 15 wherein the inorganic coating comprises chromiumor zinc.
 17. A method as in claim 15 wherein the inorganic coatingcomprises both chromium and zinc.
 18. A method as in claim 15 furthercomprising plating second sections of the at least one contact with tin,wherein tin is not located between the inorganic coatings and thesubstrates of the electrical contacts.